Placenta - Villi Development
Introduction
This page introduces an overview of aspects of the basic fetal subunit of the placenta, the placental villi development. In early placentation, each villi proceeds through a similar initial program of development. In later placentation, villi morphologically differentiate into a limited range of villi functional changes reflecting their specialization. The major initial contribution is from the trophoblast shell that surrounds the conceptus and later by the development of extraembryonic mesoderm and blood vessel differentiation.
There are three main types of trophoblast cells that differentiate:
- villous cytotrophoblasts
- extravillous cytotrophoblasts
- syncytiotrophoblasts that form by fusion of villous cytotrophoblasts
Cytotrophoblast Layer
There is a new interpretation of the changes that are occuring in the cytotrophoblast (CTB) layer during early to full-term human placenta development. Traditionally the interpretation was that the cytotrophoblast layer thinned and became discontinuous towards term. The thinning is thought due to the epithelium surface expanding at a faster rate than its volume. Two recent studies suggest that while the cytotrophoblast layer does indeed thin, it does not become discontinuous.
Syncytiotrophoblast Layer
The syncytiotrophoblast (STB) layer forms the epithelial covering of the entire villous tree. These cells are multinucleated, terminally-differentiated syncytium formed by the fusion of the underlying progenitor cytotrophoblast (CTB) cells. The process is described as "syncytialization" and is mediated by syncytin-1, an envelope protein of a human endogenous retrovirus W (HERV-W). The differentiation is regulated by chorionic gonadotropin (hCG) and the fusion of cytotrophoblast cells is ongoing during placental development.
Cellular parts derived from the syncytiotrophoblasts (apoptotic nuclei and microparticulate debris) can be shed into the maternal blood in which they are bathed. The apototic process appears to be part of the fusion mechanism between cytotrophoblast and the overlying multinucleate syncytiotrophoblast layer.
Studies have suggested that these cells are transcriptionally inactive. A recent study using a number of different detection techniques now suggests that at least some of the cells nuclei may still be transcriptionally inactive.
Mesenchymal Villi
Mesenchymal villi generate all other villous types:
- immature intermediate villi
- stem villi
- mature intermediate villi
- terminal villi
Mesenchymal villi continuously form out of the trophoblastic sprouts throughout pregnancy and have been considered the basis for growth and differentiation of the villous trees.
Villi Trimester Development
Trimester 1 and 2
In the first two trimesters they are the forerunners of the immature intermediate villi, whereas in the last trimester the mesenchymal villi are transformed into mature intermediate villi. Immature intermediate villi formed during the first two trimesters are developmental steps towards the stem villi.
Trimester 3
Mature intermediate villi develop during the last trimester, produce numerous terminal villi. Terminal villi are not active outgrowths caused by proliferation of the trophoblast, but rather passive protrusions induced by capillary coiling due to excessive longitudinal growth of the fetal capillaries within the mature intermediate villi. The arrangement of the capillary bed in the terminal villi can vary from simple U-like loops to a richly branched network due to capillary elongation and sprouting.
Some text modified from [1], see also [2]
Extravillous Trophoblast Outgrowth
During the first trimester of human pregnancy, extravillous trophoblasts (EVT) from placental villi invade the decidua temporarily occluding the spiral arteries. This occusion prevents maternal blood flow and creates a low-oxygen environment, that may play a role in the regulation of extravillous trophoblast outgrowth.
A study has shown that the early placenta ( under 11 weeks of gestation) responds to oxygen concentration, whereas villi from older placentae (11 or 12 weeks) show no differential response.[3]
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Cite this page: Hill, M.A. (2024, June 20) Embryology Placenta - Villi Development. Retrieved from https://embryology.med.unsw.edu.au/embryology/index.php/Placenta_-_Villi_Development
- © Dr Mark Hill 2024, UNSW Embryology ISBN: 978 0 7334 2609 4 - UNSW CRICOS Provider Code No. 00098G